High-Resolution Microstructure Analysis of Cork Spot Disordered Pear Fruit "Akizuki" (Pyrus pyrifolia Nakai) Using X-Ray CT.

Zhenhua Cui,Shaoling Zhang,Nannan Wang,Xinrui Xu,Yanxin Duan,Chunhui Ma,Ran Wang

doi:10.3389/fpls.2021.715124

Zhenhua Cui, Shaoling Zhang + Show 5 more

Open Access

https://doi.org/10.3389/fpls.2021.715124

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Abstract

Cork spot is one of the most damaging physiological disorders in pear fruit, causing considerable economic loss every year. However, the mechanism of cork spot occurrence requires further examination. In this study, X-ray CT scanning was applied to analyze the microstructure of pear fruit “Akizuki” (Pyrus pyrifolia), a cultivar susceptible to cork spot disorder, to elucidate the fruit texture alteration between healthy and cork spotted fruit. Results showed that cork spotted fruit had much higher porosity (9.37%) than healthy fruit (3.52%). Reconstructed three-dimensional (3D) network skeleton models showed highly branched pore channels in cork spotted fruit and a low degree of pore connectivity in healthy fruit. Even in areas of disordered fruit without cork spot, the pore throat diameter, pore length, and coordinated core number (i.e., 77, 160, and 16, respectively) were much higher than that of healthy fruit. The structure analysis of fruit core showed that core deformation only occurred in cork spotted fruit. A much more highly branched network was observed in cork spotted fruit cores compared with healthy fruit cores. High-resolution observation of flesh tissue directly demonstrated that pore size in cork spotted fruit (87 μm) was four times larger than that of healthy fruit (22 μm). Altered expression of genes related to Ca2+ transport and the uneven distribution of intracellular Ca2+ were also shown to associate with the development of cork spot disorder. Our results suggest that flesh tissue damage likely occurred prior to the initiation of cork spot. The dysfunction of long-distance and transmembrane Ca2+ transport channels could be responsible for the imbalanced distribution of Ca2+ inside the fruit, thus resulting in the development of cork spot.

Highlights

Fruit microstructure determines the mechanical and transport properties of tissues (Mebatsion et al, 2009)
Knowledge of pear fruit microstructure changes in a quantitative and qualitative 3D view is important for a better understanding of the occurrence of cork spot disorder
More information and investigation on the microstructure changes in cork spotted pear fruit are still needed to explore the mechanism of the development of cork spot disorder

Summary

Introduction

Fruit microstructure determines the mechanical and transport properties of tissues (Mebatsion et al, 2009). X-ray CT recognizes internal structures based on differences in X-ray attenuation resulting from 3D variation in the composition of the material This makes X-ray CT an excellent technique to visualize the porous structure of products on both qualitative and quantitative scales (Herremans et al, 2014a,b; Magwaza and Opara, 2014; Diels et al, 2017). Recent research (Duan et al, 2020) first attempted to non-destructively distinguish between healthy and cork spot disordered pear “Chili” (P. bretschneideri) and to preliminarily analyze the porous differences between them using X-ray CT. The objective of this study was to acquire more details of microstructure changes in cork spot disordered pear fruit “Akizuki” (P. pyrifolia) using the high-resolution X-ray CT analysis. Results of the study are expected to provide useful information for the control of cork spot disorder for orchard managers and will be valuable for further exploration of the mechanism of the development of cork spot disorder

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